Electric control circuits



Jan. 6, 1942. w GARMAN 2,269,151

ELECTRIC CONTROL CIRCUITS Filed April 24 1937 I6 Fig. l.

2 Sheets Sheet I Fig. 2.

Invent or:

George W. German by i torn ey Jan. 6, 1942 G. w. GARMAN 2,269,151 ELECTRIC CONTROL CIRCUITS Filed April 24, 1937 2 Sheets-Sheet 2 Fig. 5. /6

Fig.2 I. u w

Fig.8.

M igfi Inventor:

George W German,

6. W by fiAttorneg.

Patented J an. 6, 1942 ELECTRIC CONTROL CIRCUITS George W. Garman, Scotia, N. Y., assignor to General Electric Company, a corporation of New York Application April 24, 1937, Serial No. 138,816

14 Claims.

My invention relates to electric control circuits and more particularly to control circuits for electric valve apparatus. 7

In control circuits for electric valve apparatus, it is frequently desirable to provide arrangements to effect energization of a load circuit or a load device during an accurately determinable interval of time. It is also frequently highly desirable to effect energization of a load device or of an associated load circuit at an accurately determinable instant. These requirements are of particular importance in welding circuits energized from an alternating current circuit where it is desirable to efiect energization of the welding circuit at a predetermined time in the cycle of alternating voltage, and where it is desirable to control precisely the amount of energy supplied to the welding circuit during a predetermined interval of time. Heretofore in control circuits of this nature it Was found difficult to provide these control characteristics without employing auxiliary apparatus which was excessively expensive and which required apparatus of inordinate size and rating relative to the amount of energy to be controlled. Furthermore, the prior art arrangements have necessitated the use of a large number of auxiliary or control devices to effect this essential precision and accuracy of control.

It is an object of my invention to provide a new and improved electric valve circuit.

It is another object of my invention to provide a new and improved control circuit for electric valve apparatus.

It is a further object of my invention to provide a new and improved control circuit for effecting energization of a load circuit at an accurately determinable time during a cycle of voltage of an alternating current circuit.

It is a still further object of my invention to provide a new and improved control circuit for electric valve apparatus by virtue of which the period of energization of a Welding circuit from an alternating current supply circuit is accurately determinable.

In accordance with the illustrated embodiments of my invention, I provide circuits for accurately and precisely controlling the time and period of energization of a load circuit such as a welding circuit. The energization of the load circuit is controlled by a translating device, such as a relay or an electromagnetic contactor, which in turn is controlled by an electric valve means. I provide a control circuit for the electric valve by virtue of which the electric valve is rendered conductive at a predetermined time during the cycle of applied voltage, and whereby the interval of time during which energy is supplied to the load circuit from an alternating current supply circuit is accurately determinable. More particularly, a bias voltage is applied to control means of the electric valve tending to maintain the electric valve nonconductive and the electric valve is rendered conductive for a predetermined maximum number of half cycles of voltage of the supply circuit by impressing thereon a predetermined number of impulses of voltage each suificient to overcome the bias voltage to render the electric valve conductive. An impedance element is connected in the control circuit and is energized from a source of alternating current of peaked wave form through a capacitance and a unidirectional conducting device. The impedance element introduces in the control circuit the train of impulses of positive voltage which overcome the bias voltage.

In one embodiment of my invention I provide an electric valve means having two control members for conjointly controlling the conductivity of the electric valve means. In this arrangement a bias voltage applied to one of the control members tends to maintain the electric valve nonconductive and the train of impulses of positive voltage are applied to the other control member to render the electric valve conductive for a predetermined time or during a predetermined number of half cycles of voltage of the alternating current circuit.

Another feature of my invention is the employment of electric valve means for energizing a circuit controlling means, such as a relayor contactor having an inductive actuating coil for connecting a supply circuit to a load circuit and in which the conductivity of the electric valve is controlled by impressing on the control member thereof a bias voltage ending to maintain the electric valve nonconductive and in which there is provided an arrangement for impressing on the control member a series or train of impulses of positive voltage for rendering the electric valve means conductive to energize the actuating coil for a predetermined interval of time. The impulses of positive voltage impressed on the control member are furnished by supplying current to an impedance element connected in series relation with the actuating coil, a unidirectional conducting device, a capacitance and a source of alternating voltage of peaked wave form which charges the capacitance through these elements. The unidirectional conducting device is connected in the control circuit so that the reactive voltage appearing across the actuating coil after each period of energization is employed to establish an additional or cumulative charge on the capacitance to effect a substantial increase in the stored energy thereof, and to provide thereby a control circuit in which the time of energization of the load circuit is very accurately determinable.

For a better understanding of my invention, reference may be had to the following description taken in connection with the accompanying drawings, and its scope will be pointed out in the appended claims. Fig. 1 of the accompanying drawings shows an embodiment of my invention as applied to an electric valve control circuit for controlling the transfer of energy from an alternating current circuit to a welding circuit, and Figs. 2, 3 and 3a represent certain operating characteristics thereof. Fig. 4 is a modification of the arrangement shown in Fig. l in which the control of the electric valve means isaccomplished by controlling the energization of two control members of the electric valve'means. Fig. 5 diagrammatically-shows another embodiment of my invention in which the reactive voltn." age-across the inductive element of the circuit controlling means -is-emp1oyed to feed energy into the control circuit fonthe electric valve means, andFigs. 6, 7 and 8 represent certain operating characteristics thereof.

In Fig. 1 of the accompanying drawings there is shown an embodiment of my invention as applied to a control system for controllingan electric valve circuit. More specifically, a load circuit such as awelding circuit I is energized from an alternating current-circuit 2 through a transformer .3 having a primary winding l-which is arranged to be connected across thealternating current circuit 2. As a meansior connecting the primary winding 4 of transformer--21" tothe alternating current circuit 2, I employ a-suitable circuit controlling means or a translating device such as arelay or contactor 5 having an armature or bridging contact 6, stationary contacts land an inductive actuating coil 8. An electric:

valve .means 9, having .a controlled discharge path, is connected tobe energized'from the alternatingcurrent circuit .2 to supply current to the actuating coil 8. The. electric valve means 9 maybe of the type employing .an .ionizable medium such as a gas or a vapor and includes an anode Ill, a cathode. and .a control member or grid l2. The electric valve meansaa may also include an additional control membersuch as a screen grid l3 which is connectedto the cathode I l. Although in the arrangement. of my invention shown in Fig. .11 have employed only one, electric valve means iorHsupp-lying current to the actuating coil 8 of contactor 5, it is...to be understood that I may employ, if. desired, .suitable electric valve means such as aypair of oppositely disposed electric valve means .to supply current to the actuating coil tduring both half cycles of voltage of the alternating current circuit 2. It is also to be understood that, if desired, I may employ electric valve means of the high vacuum type to controlthe energizaticn of the actuating coil '8.

As an' agency for controlling the conductivity of the electric valve means 9 to render the electric valve means conductive at apredetermined. instant in thecycle of voltage applied thereto and. to maintain the electric valve conductivefor a predetermined consecutivemumber, of positive .half cycles of voltageof thealternatingcurrent circuit 2, I provide a control circuit it including a source of negative unidirectional biasing voltage which is impressed on control member l2 tending to maintain the electric valve 9 nonconductive. This source of negative bias voltage may be provided by any of the arrangements Well known in the art and I have chosen to show this arrangement as comprising a circuit E including a transformer it which is energized from the alternating current circuit 2, a voltage divider including a resistance I! having an adjustable contact l8, a resistance H], a capacitance iii connected in shunt relation with the resistance iii and a unidirectional conducting device H for energizing the resistance [9 and the capacitance 20 from the voltage divider. The unidirectional conducting device 2i may be of the electronic type or of the contact-rectifying type and is connected in the circuit so that the left-hand plate of the capacitance is charged negatively tending to impress on the control member i2 oi electric valve means 9 a negative unidirectional bias voltage. A suitable current limiting resistance 22 .may be connected in series relation with the resistance 19 and the control member 12, and a capacitance23- may be connected across the cathode ll andcontrol member I2- of electric-valve 9 to absorb. extraneous transient voltages which may exist in the control ircuit Hi.

I provide an impedance element such as a resistance 24 for introducing in the control circuit l4 positive impulses of voltage sufiicient in magnitude to overcome the negative bias voltageprovided by resistance l9 and capacitance 2t to render the electric valve means 9 conductive. The resistance 24 is energized bya suitable source of periodic current so that the voltageappearing across the terminals of this resistance .is sufficient to render. the electric valve 9 conductive at predetermined times. Thissource of periodic voltage maybe supplied .by an alternating current circuit or maybe providedby an impulse generator, and in the arrangementofzmy invention diagrammaticallyshownin Fig. .1 I employ an alternating voltage of peaked Wave form supplied by a saturable inductivedevice 25 and a unidirectional conductingdevice :25. The saturable inductive device25 .issprovided with a core member 21, a saturable section 28, a primary exciting winding 29.and asecondary control winding 3B which is associatedwith .thesaturable section 28. The primary.actuating winding 29 'may be energized from the alternating. current circuit 2 through .a suitable adjustablerresistance 3E. The adjustable resistance 3 I. provides. an arrangement for controlling, the phase of the alternating voltage of peaked wave form. generated in secondary winding 30 relative to the voltage of the alternating'currentcircuit 2. As a means for controlling the number of impulses of voltage appearing across the terminals of resistanceQ-l which .are effective to render theelectric valve .means conductive, I employ an adjustable energy storage device such as a capacitance 32 which is connected inseries relation with the resistance 24, unidirectional conducting device 26 and secondary Winding 30 of inductive device 25. A suitable circuit controlling means, such as a switch 33, may be connected in series relation between the capacitance 32 and. resistancefii and may be employed to close a discharge circuit for the capacitance 32. The discharge circuit may include an adjustable resistance .34. The capacitance 32 serves to control-the current supplied to the resistance. 24and thereby: controls the magnitudes 01' the positive voltage impulses introduced in the control circuit l4. Moreover, the capacitance 32 serves to control the maximum number of consecutive impulses of positive voltage which render the electric valve means 8 conductive.

The operation of the embodiment of my invention diagrammatically shown in Fig. 1 will be explained by considering the system when it is arranged to operate to effect energization of the welding circuit for a predetermined interval of time. When the switch 33 is in the position shown in the drawings, the capacitance 32 will be discharged and the electric valve means 9 will be maintained non-conductive by virtue of the negative unidirectional bias voltage impressed on control member I2 by resistance l9 and capacitance 20. If the switch 33 is moved to the lower position, the inductive device 25 will operate to charge the capacitance 32 through a circuit including secondary winding 30, unidirectional conducting device 26 and resistance 24, establishing on the lower plate of capacitance 32 a positive charge. Since only unidirectional current will flow in this circuit, the voltage appearing across the terminals of resistance 24 will be periodic and the magnitude of this voltage will depend upon the rate of charging the capacitance 32, or, in other words, will depend upon the current in this circuit. By the proper adjustment of tap l8 assocated with resistance H, the negative unidirectional bias voltage may be adjusted so that the voltage introduced in the circuit l4 by resistance 24 is sufficient to render the electric valve 9 conductive. Since the capacitance 32 is now partially charged, the next succeeding impulse of current flowing through the resistance 24 will be smaller in magnitude than the preceding one due to the fact that the net voltage acting on the circuit is substantially reduced by virtue of the charge in capacitance 32. It is to be understood that by adjustment of the negative unidirectional bias voltage I provide an arrangement whereby the time of energization of the actuating coil 8 is controlled.

The operation of the arrangement of Fig. 1

may be better understood by referring to the operating characteristics represented in Figs. 2, 3 and 3a. Considering Fig. 2 in particular, the curve A represents the voltage appearing across actuating coil 8 of contactor 5 during one cycle of alternating voltage of the circuit 2. It is assumed that the bridging member 6 of contactor 5 will be maintained in engagement with contacts l for a complete cycle of voltage even though the electric valve 9 is unidirectional. The current is maintained through th actuating coil 8 during the negative portion of the .cycle by virtue of the inductance thereof.

Re- ;ferring now to Fig. 3 the curves B, C, D, E, F, G, H and J represent the impulses of positive voltage introduced in circuit l4 by resistance 24. The interval between each of these curves represents 360 electrical degrees or one cycle of voltage. The distances a, b, c, d, e, f, g, h represent the charge on capacitance 32 or may be considered to indicate the voltage existing in the circuit l4 due to the charge of capacitance 32. In Fig. 3a, the line 2: represents the negative bias voltage introduced in circuit I4 by resistance l9 and capacitance 2|]. The magnitude of this bias voltage, represented by the distance from the line a: to zero axis, may be controlled by adjusting contact 18. The portions of curves B, C, D, E and F above the zero axis represent the net positive voltage impressed on control member l2, neglecting the voltage drop incident to flow of current through resistance 22. After the time corresponding to the position of curve F, it will be understood that the next succeeding impulse of voltage, represented by curve G, generated by the inductive device 25 will not supply suflicient current to resistance 24 to furnish a voltage suflicient in magnitude to overcome the negative bias voltage and the electric valve means 9 will not be rendered conductive at the time corresponding to the position of curve G. Accordingly, the actuating coil 8 of contactor 5 will be deenergized and the period of energization of the welding circuit I will be terminated. By taking into consideration the inertia of the contactor 5, the time of energization of the welding circuit I may be precisely controlled and furthermore the period of energization of the welding circuit l is accurately determinable. By increasing the magnitude of the capacitance 22, it is to be understood that the period of energization of the welding circuit I will be increased and conversely by decreasing the size of the capacitance 32 the period of energization of the welding circuit 1 will be decreased. Furthermore, the time of energization of the welding circuit I may be controlled by adjusting contact l8 to control the negative bias voltage. As the negative bias voltage is increased, the time of energization is decreased; and conversely, as the negative bias voltage is decreased, the time of energization is increased. To reset the circuit, the switch 33 is moved to the upper position discharging the capacitance 32 through the resistance 34.

Although in the arrangement of my invention shown in Fig. 1 I have chosen to supply the periodic voltage or current for charging the capac'i tance 32 by means of a saturable inductive device, it is to be understood that my invention in its broader aspects may include those arrangements where the periodic voltage or current is generated by other arrangements such as an electric valve periodic current impulse generator.

One of the principal advantages of my invention is the accurate timing control efiected by employing a periodic control voltage of peaked wave form. When such a periodic voltage is used, the positive voltage impulses introduced in circuit l4 will also be of peaked wave form to render the electric valve 9 conductive at a predetermined instant in the cycle of voltage of the alternating current circuit 2. Moreover, it is to be noted that the actuating coil of the contactor 5 is connected directly in circuit with the electric valve means 9, thereby eliminating the necessity for expensive auxiliary control equipment.

The arrangement of my invention diagrammatically shown in Fig. 4 is similar in many respects to that shown in Fig. 1 and corresponding elements have been assigned like reference numerals. The electric valve means 9 includes a discharge path the conductivity of which is controlled conjointly by control members 12 and 13. In other words, the electric valve 9 may be maintained nonconductive by impressing on the control member l3 alternating voltages which tend to maintain the electric valve nonconductive and the valve may be rendered conductive by impressing on control member l2 a positive voltage of sufficient magnitude tending to render the control member l3 ineffective and thereby rendering the valve conductive. The electric valve 9 may be of the high vacuum type or it may be :ofthei typeiemployingan ionizable medium such .the alternating current circuit 2. the arrangement shown the bias voltage imrangement of Figs 1.

.tion. By

.asa gasor a'vapon:

;In order toimpress on the. control member l3 asuitable bias voltageatending to maintainthe electric valve 9 nonconductive, I employ a air-f cuit35 including-atransformer 36, a voltage divider including: a resistance 3'! and an adjustable contact33; anda current limiting resistance 39. .The circuit35 may be energized from any suitable source of current and I have chosen to' show' the transformer 36 as being connected to Although in pressed on control member I 3 is alternating, it

is to be understood that I may employ a unidi-;-;

rectional bias voltage if desired.

The operation of the embodiment of my invention shown in Fig. 4 i substantially the same as that explained in connection with the ar- By the adjustment of the,

contact or tap 38 -a predeterminedselected bias voltage is impressed on the control member l3 tending to maintain the electric valve 9 nonconductive. The phase of the alternating bias voltage impressed on control member I3 is pref-. erably 180 degrees out of phase with respect to the voltage impressed on anode Hi. When the switch 33-15 moved to the lower position, there will be impressed on control member l2 a series or train of impulses of positive voltage sufficient to render the electric valve 9 conductive to maintain the contactor in the closed position to effect energization of the load circuit i fora corresponding interval of time. As the capacitance 32 becomes charged by the impulses of. device 25' current supplied by the inductive through unidirectional.conducting device 26 and resistance 24, the magnitude of these impulses progressively decrease in value until the voltage appearing across resistance 24 is insufiicient to,

render the electric valve'9 conductive. When the capacitance 32 is suificiently charged, the energization of the actuating coil 8 of contactor I 5-willbe discontinued and the circuit to the primary windingzfil of transformer 3 will be opened effecting deenergization of the load circuit I. To reset the circuit, the switch--33 is moved to the upper position thereby discharging the capacitance 32 through the resistance 35-.

Th arrangement of my invention shown in Fig. 5 is similar in many respects to that of Fig.

' 1 and corresponding elements have been assigned like reference numerals. In'the arrangement of Fig. 5, I employ a control circuit'which is'susceptible of great precision in accurately determining and controlling theinterval of-energivbroadlyclaimed-in a copending application of Harry.L. Palmer, Serial No. 138,776, filed A ril. 24, 1937, entitled Electric control circuits and assigned to the assignee of the present applicainterconnecting the! anode-cathode circuit and the control circuit Hi, energy is transferred. from the-former circuit to the latter to build up the charge in capacitance. 32 to effect more precise control of the interval or period of energization of.v the actuating. coil 8 by vthelelectric valve means 9. More specifically, I provide an arrangement for utilizingthe energy stored in the inductive actuating element 8 of contactor 5 immediately following each period of energization of the inductive actuating element by the electric valve means 9.

The operation of the embodiment of my invenution shown in Fig. 5 will be explained by considering the system when it is adjusted to effect energization of the load circuit I for an interval of time corresponding to three cycles of the alternating current circuit 2. The electric valve 9 will be maintained nonconductive bythe negative unidirectional bias voltage'impressed on control member I2 by resistance I9 and capacitanceZO, and when the switch 33 is moved to the upper position there will appear across resistance '49 a train of impulses of positive voltage suflicient to overcome the negativebias voltage rendering the electric valve 9 conductive. Referring to the operating characteristics shown in Figs. 6 and 7, the curve K represents the voltage appearing across the inductive actuating coil 8 of contactor 5. The positive portion: of this curve represents the voltage'impressed thereon through the electric valve 9 by the alternating current circuit 2 and the negative portion thereof represents-the voltage appearing across the terminals of the actuating elementzs due to the energy stored in the inductive actuating coil. It will be understood that the unidirectional conducting device 26 is connected in thecircuit not only to permit energization .of the'capacitance 32 by thesaturable inductive device 25 during half cycles of predetermined polarity of peaked voltage, but is also connected to permit the utilization of the negative portion of curve'K to establish an additional or cumulative charge in capacitance 32. CurvesL, M and N of Fig. 7 represent the rectified impulses of voltage supplied by the saturable inductive device 25-and the interval therebetween corresponds to 360 electrical degrees. The amount of'energy stored in the capacitance 32 by the first unidirectional impulse of current may be represented by the-distance a and the increment of charge stored in the capacitance 32 by utilizing the reactive voltage of the actuating coil 8 may be represented by the distance is. It will be understood that the amount of energy transferred to the capacitance '32 by utilizing the stored energy of the actuating coil 8 materially increases the storedenergy of capacitance 32 to permit accurate and precise control of the period of energization of the load circuit l without sacrificing the precision of control available by rendering electric valve means conductive by the use of voltages of peaked wave form introduced 'in the control circuit I4. This feature isof great importance where it is desired to-render the electric valve means conductive at a predetermined instant and where it is also desirable to effect precise control of theperiod of energization. As'will be under stoodby referring to Fig. 8,'the impulses of voltage represented by curves L, M and N are efiective to render the electric valve means 9 conductive, but-the next succeeding impulse of positive voltagesupplied by the inductive device .25 will be ineffective to produce across resistance 40 -a voltage sufiicient to render electric valve means 9 conductive, in this way effecting energization- -of the load circuit I during .a period corresponding to three cycles of voltage of the alternating current circuit 2..

'While Ihave shown and described myinvention as applied to a particular system of connections and a embodying various devices diagrammatically shown, it will be obvious to those skilled in the art that changes and modifications may be made without departing from my invention, and I, therefore, aim in the appended claims to cover all such changes and modifications as fall within the true spirit and scope of my invention.

What I claim as new and desire to secure by Letters Patent of the United States is:

1. In combination, an alternating current circuit, a translating device, an electric valve means interposed between said circuit and said device for energizing said device, said electric valve means including a control member for controlling the conductivity thereof, and a control circuit for energizing said control member comprising means for impressing on said control member a negative unidirectional bias voltage tending to maintain said electric valve means nonconductive, an impedance element and means connected across said impedance element comprising a serially connected source of periodic voltage of peaked wave form, a unidirectional conducting device connected in series relation with said source of voltage of peaked wave form and a capacitancefor supplying a predetermined number of impulses of positive voltage to overcome said bias voltage torender said electric valve means conductive for a corresponding number of half cycles of voltage of said alternating current circuit.

.2. In combination, an alternating current circuit, a translating device, an electric valve means for energizing said translating device from said alternating current circuit and including acontrol member, means for providing a unidirectional bias voltage of substantially constant value, a source of voltage of peaked wave form,

a capacitance, an impedance element, and a unidirectional conducting device for charging said capacitance from said source of voltage 01. peaked wave form through said impedance element to provide a control voltage sufilcient to overcome said bias voltage to render said electric valve means conductive, said control voltage being responsive to the rate of charging said capacitance to control the maximum number of consecutive half cycles of voltage of predetermined sign of said alternating current circuit during which said electric valve means is rendered. conductive.

3. In combination, an alternating current supply circuit, a translating device, an electric valve means for energizing said translating device from said supply circuit and including a control member for controlling the conductivity thereof, means for impressing on said control member a unidirectional bias voltage of substantially constant value, an impedance element connected in series relation therewith, a saturable inductive device for providing an alternating voltage of peaked wave form, a capacitance, and a unidirectional conducting device for charging said capacitance from said inductive device through said impedance element to provide a voltage sufiicient to overcome said bias voltage to render said electric valve means conductive for a predetermined number of consecutive half cycles of voltage of predetermined polarity.

4. In combination, an alternating current supply circuit, a load circuit, means for connecting said supply circuit to said load circuit, electric valve means for energizing said first mentioned means and including a control member for conid'impressed on said control member.

trolling the conductivity thereof, and a control circuit for energizing said control member comprising means for providing a unidirectional bias voltage of substantially constant value, an impedance element connected in series relation therewith, a capacitance, a source of Voltage of peaked wave form and a unidirectional conducting device for charging said capacitance from said source of voltage of peaked wave form through said impedance element to supply voltage impulses suiiicient to overcome said bias voltage to render said electric valve means conductive during a predetermined consecutive number of positive half cycles of voltage of said supply circuit.

5. In an excitation circuit for an electric valve means having a control member, the combination of a source of negative unidirectional bias voltage tending to maintain said electric valve means nonconductive, an impedance element, and means for energizing said impedance element to supply a positive voltage to overcome said bias voltage so as to render the electric valve means conductive comprising a seriallyconnected source of voltage of peaked wave form and a capacitance connected directly across said impedance element.

6. In an excitation circuit for an electric valve means having a control member, the combination of means for supplying a negative unidirectional bias voltage tending to maintain the electric valve means nonconductive, an impedance element connected in series relation with said means, a capacitance, a unidirectional conducting device and a source of alternating voltage of peaked wave form for charging said capacitance through said impedance element and said unidirectional conducting device to supply positive impulses of voltage progressively decreasing in magnitude to overcome said bias voltage so as to render the electric valve means conductive, said impedance element and said capacitancebeing proportioned so that only a predetermined number of positive impulses of voltage are '7. In an excitation circuit for an electric valve means including two control members for conjointly controlling the conductivity thereof, the combination of means for impressing on one of said control members a bias voltage tending to maintain said electric valve means nonconductive, and means for impressing on the other of said control members impulses of voltage sumcient to overcome the effect of said bias voltage to render said electric valve means conductive comprising an impedance element connected in circuit with the other of said control members, a capacitance, a unidirectional conducting device and a source of periodic current for charging said capacitance through said impedance element and said unidirectional conducting device.

8. In combination, an alternating current circuit, a translating device, electric valve means for transferring energy to said translating device from said alternating current circuit, said electric valve means comprising at least two control members for conjointly controlling the conductivity thereof, means energized from said alternating current circuit for impressing on one of said control members a voltage tending to maintain said electric valve means nonconductive, and means for energizing the other of said control memebrs to overcome the effect of said bias volt age to render said electric valve means conductiveduring a predetermined number of half cyclesv of voltage of said alternating current circuit comprising animpedance element connected in circuit with the other of said control members, a capacitance, a unidirectional conducting device and a source of alternating voltage of peaked Wave form for charging said capacitance through said impedance element and said unidirectional conducting device.

'9. In combination, an alternating current circuit, a load circuit, a circuit controlling means for connecting said alternating current circuit to said load circuit and including an actuating coil, an electric valve means connected in circuit with said. actuating coil for transmitting current thereto from said alternating current circuit, said electric valve means comprising a control member for controlling the conductivity thereof, means for'impressing on said control member a negative unidirectional'bias voltage tending-to maintain said electric valve means nonconductive, an impedance element connected'in circuit with. said controlmember and .said means, and means for energizing said. impedance element through said, actuating coil'to impress on said control member a predetermined number of impulsesrof positive voltage to render said electric valve-means. conductive to transmit a number of impulsesnofjcurrent to, said actuating coil comprising ,inseries relation atcapacitan'ce, aunidirectional, conducting device and a source of periodic current, said. unidirectional conducting device being connected to utilize the reactive voltage appearing across saidr coil tov charge said capacitance during theintervals between said impulses of current 10. In combination, .analternating current circuit a translatingrdevice havingan inductive element, electric valve means for energizing said inductive element from said. alternating. current circuit during ;only half cycles of voltage of one polarity, said electric valve/means having a control--member for controlling it the conductivity thereof, and a control circuit for energizing said control member comprising means lforimpressing onsaid control member a bias voltage tending .to maintain said electric valve means .nonconductive, an-.impedance -element, means for energizing said impedance element to supply impulses of' voltage to-overcome said bias voltage to ,render said valve means conductive duringaprede'termined number of half cycles of voltage of said one polarity includinga capacitance, arunidirectionalconducting device and asourcelof periodic current for charging. said capacitance... through said inductive element-,said impedanceelement and said unidirectional conductingdevice, said unidirectional conductingdevice being connected to chargesaid capacitance in'accordance with the voltage appearing across said inductive element immediately .aiter each period of energization by said. electric valve ,means.

11- In combination, an alternating current supply circuit, a load circuit, electric translating apparatus foritransmittin to said load circuit a predetermined number of half cycles of currentderived from said su'oolv circuit and comprising an electric dischar e device havin a control electrode, means for impressin on said control electrode a bias volta e tending to maintain said electric discharge device ncnconducting, control means'for said electric discharge device for 'im pressing on said control electrode a-predetermined number of positive impulses of voltage progressively decreasing in ;magnitude and reach sufficient toyovercome the'effect of said bias volt-i age thereby rendering said electric discharge-device conducting for a corresponding number of half cycles of voltage of said supply circuit and comprising peaking means for producing a periodic voltage of peaked Waveform, a capacitance, an impedance element, a rectifier connected in series relation with said impedance element and said peaking means for charging said capacitance through said impedance element, said peaking means serving to synchronize the operation of said control means with the voltage of said supply circuit by controlling the phase relation of said positive impulses relative to the voltage of said supply circuit, a switch connected in series relation'with said capacitance for initiating the generation of said positive impulses of voltage,

and means for supplying said peaking means with current derived from said supply circuit.

12. In combination, an alternating current supply circuit, a load circuit, electric translating apparatus for transmitting to said load circuit a predetermined number of half cyclesof current derived from said supply circuit and comprising an electric discharge device having a control electrode; means for impressing on said control electrode a bias voltage tending to maintain said electric discharge device nonconducting, control means for impressing on said control electrode a predetermined number: of positive impulses of voltage progressively'decreasingin magnitude and each sufficient to overcome the effect of said bias voltage thereby rendering said electric discharge device conducting for a corresponding number of halflcycles of, voltage of said supply circuit and comprising a saturable inductive device for producingaperiodic voltage of peaked wave form, a capacitance,-. an impedance element and, a ,rectie fier for charging saidcapacitance through said impedance element fromsaid saturable inductive device, saidsaturable inductive device serving to.

synchronize the operation of said controlmeans withlthe voltageof saidfsupplycircuit by controlling .the phase relation .of said. positive im-. pulses relative to th'evoltageof said supply circuit, a switch connected :in series relation with said :capacitancefor initiating the generation of,

said positive impulses of voltage,and means for energizing said saturable inductive :device from said supply circuits 13.'In combination, an alternating current supply circuit, a load circuit, electric translating apparatusfor transmitting to said load circuit a predetermined number of half cycles of current derived from said supply circuit and comprising anelectric discharge-device havinga control electrode, means forimpressing on said control electrode'a bias voltage'tending to'maintain said electric discharge device enonconducting, control means forimpressingon said control electrode a predetermined number of positive impulses-of voltage progressively decreasing in magnitude and each sufficient to overcome theeffect of said bias voltage-thereby rendering said electric discharge device conducting foracorresponding number of half cycles of voltage ofsaid supply circuit and comprising a capacitance; a saturable inductive device for producing a periodic voltageoi' peaked waveform, an impedance element and a rectifier for transmitting impulsesofcurrent through said :impedance elementfrom said saturable device, said saturable inductive device; serving .to synchronize the operation of said control means with respect to the voltage of said supply circuit by controlling the phase relation of said positive impulses of voltage, a switch connected in series relation with said capacitance for initiating the generation of said positive impulses of voltage, a discharge circuit for said capacitance, and phase shifting means connected between said supply circuit and said saturable inductive device for controlling the phase relation of said positive impulses of voltage relative to the voltage of said supply circuit.

14. In combination, an alternating current supply circuit, a load circuit, electric translating apparatus for transmitting to said load circuit a predetermined number of half cycles of current derived from said supply circuit and comprising an electric discharge device having a control electrode, means for impressing on said control electrode a bias voltage tending to maintain said electric discharge device nonconducing, control means for impressing on said control electrode a predetermined number of positive impulses of voltage progressively decreasing in magnitude and each sufiicient to overcome the efiect of said bias voltage thereby rendering said electric discharge device conducting for a corresponding number of half cycles of voltage of said supply circuit and comprising a saturable inductive device for producing a periodic voltage of peaked wave form, a capacitance, an impedance element and a rectifier for charging said capacitance from said inductive device through said impedance element, said saturable inductive device serving to synchronize the operation of said control means relative to the voltage of said supply circuit, a switch connected in circuit with said capacitance for initiating generation of said positive impulses, and means connected between said supply circuit and said saturable inductive device for adjusting the phase of said positive impulses of voltage relative to the voltage of said supply circuit and for controlling the magnitude of the current transmitted to said load circuit.

GEORGE W. GARMAN. 

